Communications receiver using multi-band transmit blocking filters

ABSTRACT

Communications receivers and devices are disclosed. A communications receiver includes a low noise amplifier; a multi-band transmit blocking filter having a first port connected to an output of the low noise amplifier, and an RF analog-to-digital converter having an input connected to a second port of the multi-band transmit blocking filter. The multi-band transmit filter passes the receive frequencies of a group of two or more LTE bands, where a first receive frequency range of a first band in the group and a second receive frequency range of a second band in the group are disjoint and not subsets of a receive frequency range of a third band in the group, and stops the transmit frequencies of at least some bands in the group.

RELATED APPLICATIONS

This application claims priority from Provisional Patent Application62/448,781, filed Jan. 20, 2017, and Provisional Patent Application62/455,040, filed Feb. 6, 2017, both of which are incorporated herein byreference.

NOTICE OF COPYRIGHTS AND TRADE DRESS

A portion of the disclosure of this patent document contains materialwhich is subject to copyright protection. This patent document may showand/or describe matter which is or may become trade dress of the owner.The copyright and trade dress owner has no objection to the facsimilereproduction by anyone of the patent disclosure as it appears in thePatent and Trademark Office patent files or records, but otherwisereserves all copyright and trade dress rights whatsoever.

BACKGROUND Field

This disclosure relates to radio frequency filters using surfaceacoustic wave (SAW) resonators, and specifically to communicationsequipment incorporating such filters.

Description of the Related Art

A radio frequency (RF) filter is a two-terminal device configured topass some frequencies and to stop other frequencies, where “pass” meanstransmit with relatively low insertion loss and “stop” means block orsubstantially attenuate. The range of frequencies passed by a filter isreferred to as the “passband” of the filter. The range of frequenciesstopped by such a filter is referred to as the “stopband” of the filter.A typical RF filter has at least one passband and at least one stopband.Specific requirements on a passband or stopband depend on the specificapplication. For example, a “passband” may be defined as a frequencyrange where the insertion loss of a filter is less than a defined valuesuch as one dB, two dB, or three dB. A “stopband” may be defined as afrequency range where the insertion loss of a filter is greater than adefined value such as twenty dB, twenty-five dB, forty dB, or greaterdepending on application. A “multiple-passband” filter is a filter thatprovides multiple noncontiguous passbands separated by stopbands. Forexample, a dual-passband filter has two disjoint frequency ranges withlow insertion loss separated by a stopband having high insertion loss.

RF filters are used in communications systems where information istransmitted over wireless links. For example, RF filters may be found inthe RF front-ends of base stations, mobile telephone and computingdevices, satellite transceivers and ground stations, IoT (Internet ofThings) devices, laptop computers and tablets, fixed point radio links,and other communications systems. RF filters are also used in radar andelectronic and information warfare systems.

RF filters typically require many design trade-offs to achieve, for eachspecific application, the best compromise between such performanceparameters as insertion loss, rejection, isolation, power handling,linearity, size and cost. Specific design and manufacturing methods andenhancements can benefit simultaneously one or several of theserequirements.

Performance enhancements to the RF filters in a wireless system can havebroad impact to system performance. Improvements in RF filters can beleveraged to provide system performance improvements such as larger cellsize, longer battery life, higher data rates, greater network capacity,lower cost, enhanced security, higher reliability, etc. Theseimprovements can be realized at many levels of the wireless system bothseparately and in combination, for example at the RF module, RFtransceiver, mobile or fixed sub-system, or network levels.

Surface acoustic wave (SAW) resonators are used in a variety of RFfilters including band-reject filters, band-pass filters, duplexers, andmultiplexers. A duplexer is a radio frequency filter device that allowssimultaneous transmission in a first frequency band and reception in asecond frequency band (different from the first frequency band) using acommon antenna. A multiplexer is a radio frequency filter with more thantwo input or output ports with multiple passbands. A triplexer is afour-port multiplexer with three passbands.

As shown in FIG. 1, a typical SAW resonator 100 is formed by thin filmconductor patterns formed on a surface of a substrate 105 made of apiezoelectric material such as quartz, lithium niobate, lithiumtantalate, or lanthanum gallium silicate. The substrate 105 is commonlya single-crystal slab of the piezoelectric material, or a compositesubstrate including a thin single-crystal wafer of the piezoelectricmaterial bonded to another material such as silicon, sapphire, orquartz. A composite substrate is commonly used to provide a thermalexpansion coefficient different from the thermal expansion coefficientof the single-crystal piezoelectric material alone. A firstinter-digital transducer (IDT) 110 includes a plurality of parallelconductors. A radio frequency or microwave signal applied to the firstIDT 110 via an input terminal IN generates an acoustic wave on thesurface of the substrate 105. As shown in FIG. 1, the surface acousticwave will propagate in the left-right direction. A second IDT 120converts the acoustic wave back into a radio frequency or microwavesignal at an output terminal OUT. The conductors of the second IDT 120are interleaved with the conductors of the first IDT 110 as shown. Inother typical SAW resonator configurations (not shown), the conductorsforming the second IDT are disposed on the surface of the substrate 105adjacent to, or separated from, the conductors forming the first IDT.Also, extra fingers (commonly called “dummy” fingers) are sometimesformed opposite to the ends of the IDT fingers and connected to the INand OUT bus bars of the first and second IDTs 110 and 120. Gratingreflectors 130, 135 are disposed on the substrate to confine most of theenergy of the acoustic waves to the area of the substrate occupied bythe first and second IDTs 110, 120. The grating reflectors 130, 135float or are connected to either the IN terminal or the OUT terminal. Ingeneral, the SAW resonator 100 is bi-directional, and the IN and OUTterminal designations may be transposed.

The electro-acoustic coupling between the first IDT 110 and the secondIDT 120 is highly frequency-dependent. The basic behavior of acousticresonators (SAW, bulk acoustic wave, film bulk acoustic wave, etc.) iscommonly described using the Butterworth Van Dyke (BVD) circuit model asshown in FIG. 2A. The BVD circuit model consists of a motional arm and astatic arm. The motional arm includes a motional inductance L_(m), amotional capacitance C_(m), and a resistance R_(m). The static armincludes a static capacitance C₀ and a resistance R₀. While the BVDmodel does not fully describe the behavior of an acoustic resonator, itdoes a good job of modeling the two primary resonances that are used todesign band-pass filters, duplexers, and multiplexers (multiplexers arefilters with more than 2 input or output ports with multiple passbands).

The first primary resonance of the BVD model is the motional resonancecaused by the series combination of the motional inductance L_(m) andthe motional capacitance C_(m). The second primary resonance of the BVDmodel is the anti-resonance caused by the combination of the motionalinductance L_(m), the motional capacitance C_(m), and the staticcapacitance C₀. In a lossless resonator (R_(m)=R₀=0), the frequencyF_(r) of the motional resonance is given by

$\begin{matrix}{F_{r} = \frac{1}{2\pi\sqrt{L_{m}C_{m}}}} & (1)\end{matrix}$The frequency F_(a) of the anti-resonance is given by

$\begin{matrix}{F_{a} = {F_{r}\sqrt{1 + \frac{1}{\gamma}}}} & (2)\end{matrix}$where γ=C₀/C_(m) is a characteristic of the substrate upon which the SAWresonator is fabricated. γ is dependent on both the material and theorientation of the crystalline axes of the substrate, as well as thephysical design of the IDTs.

The frequencies of the motional resonance and the anti-resonance aredetermined primarily by the pitch and orientation of the interdigitatedconductors, the choice of substrate material, and the crystallographicorientation of the substrate material.

FIG. 2B is a plot of the admittance of a theoretical lossless acousticresonator. The admittance exhibits a motional resonance 212 where theadmittance of the resonator approaches infinity, and an anti-resonance214 where the admittance of the resonator approaches zero. Inover-simplified terms, the lossless acoustic resonator can be considereda short circuit at the frequency of the motional resonance 212 and anopen circuit at the frequency of the anti-resonance 214. The frequenciesof the motional resonance 212 and the anti-resonance 214 arerepresentative, and a resonator may be designed for other frequencies.

Cellular telephones operate in various bands defined by industry orgovernmental standards. For example, the 3GPP LTE (Third GenerationPartnership Project Long Term Evolution) standard (ETSA TS 136 101V13.3.0) defines 50 different bands over a frequency range of about 450MHz to greater than 5000 MHz. These are referred to herein as “LTEbands”. Each of the LTE bands consists of a frequency range or a pair ofdisjoint frequency ranges used for cellular telephone communications.For example, LTE band 12, which is used in the United States and Canada,employs the frequency range from 699 MHz to 716 MHz for communicationsfrom the cellular device to the cellular network and the frequency rangefrom 729 MHz to 746 MHz for communications from the network to thedevice. LTE band 40, used in several countries in Asia, employs thefrequency range from 2300 MHz to 2400 MHz for communications in bothdirections. A few LTE bands, such as LTE band 67, are defined fordownlink use only, which is to say the band defines a frequency rangewhere a user device may receive, but not transmit. Some LTE bandsoverlap, or are superimposed on other LTE bands. For example, LTE bands4 and 10 are subsets of LTE band 66.

All of bands defined by the 3GPP LTE standard are not currently in use,and only one or a few bands are typically used in any particularcountry. Further, different cellular service providers in any givencountry may each have frequency allocations within one or multiplebands. To allow international roaming, it is desirable for cellularphones to be capable of operation in as many frequency bands aspossible.

Carrier aggregation is a technique to increase data rates bytransmitting multiple signals or carriers to a cellular phone. Themultiple signals may be within the same band or in multiple bands insituations where the service provider has frequency allocations inmultiple bands. To facilitate carrier aggregation, it is desirable forcellular phones to be capable of simultaneous operation in multiplefrequency bands.

DESCRIPTION OF THE DRAWINGS

FIG. 1 is a simplified schematic plan view of a SAW resonator.

FIG. 2A is an equivalent circuit of a SAW resonator.

FIG. 2B is graph of the admittance of a lossless SAW resonator.

FIG. 3 is a block diagram of a radio frequency (RF) system for acommunications device.

FIG. 4 is a block diagram of another radio frequency (RF) system for acommunications device.

FIG. 5 is a block diagram of another radio frequency (RF) system for acommunications device.

FIG. 6 is a block diagram of a low bands multi-band transmit blockingfilter.

FIG. 7 is a block diagram of a mid/high bands multi-band transmitblocking filter.

FIG. 8 is a block diagram of a high bands multi-band transmit blockingfilter.

FIG. 9 is a block diagram of a surface acoustic wave dual-passbandfilter.

FIG. 10 is a schematic diagram of a first exemplary SAW dual-passbandfilter.

FIG. 11 is a chart showing S(2,1) of the first exemplary SAWdual-passband filter of FIG. 10.

FIG. 12 is a schematic diagram of a second exemplary SAW dual-passbandfilter.

FIG. 13 is a chart showing S(2,1) of the second exemplary SAWdual-passband filter of FIG. 12.

FIG. 14 is a schematic diagram of a third exemplary SAW multi-bandfilter.

FIG. 15 is a chart showing S(2,1) of the third exemplary SAW multi-bandfilter of FIG. 14.

FIG. 16 is a schematic diagram of a fourth exemplary SAW dual-passbandfilter.

FIG. 17 is a chart showing S(2,1) of the fourth exemplary SAWdual-passband filter of FIG. 16.

FIG. 18 is a schematic diagram of another exemplary dual-passband SAWfilter.

FIG. 19 is a chart showing S(2,1) of the exemplary dual-passband SAWfilter of FIG. 18.

Throughout this description, elements appearing in figures are assignedthree-digit reference designators, where the most significant digit isthe figure number where the element is first shown and the two leastsignificant digits are specific to the element. An element that is notdescribed in conjunction with a figure may be presumed to have the samecharacteristics and function as a previously-described element havingthe same reference designator.

DETAILED DESCRIPTION

Description of Apparatus

FIG. 3 is a block diagram of a radio 300 for use in a communicationsdevice. The radio 300 may be configured for communicating in one of theLTE bands. The radio 300 includes an antenna 312, a duplexer 314, areceiver 316, and a transmitter 318. The duplexer 314 includes a receiveport for connection to the receiver 316, a transmit port for connectionto the transmitter 318, and an antenna port for connection to theantenna 312. Within the duplexer 314, a receive filter is coupledbetween the receive port and the antenna port, and a transmit filter iscoupled between the antenna port and the transmit port. The receivefilter is configured to pass the receive frequency range and block thetransmit frequency range of the associated LTE band. The transmit filteris configured to pass the transmit frequency range and block the receivefrequency range, such that sidebands of the transmit signal that fallwithin the receive frequency range are attenuated. The terms “receivefrequency range” and “transmit frequency range” are from the perspectiveof a user device. The receive frequency range and the transmit frequencyrange are equivalent to the downlink frequency range and uplinkfrequency range as defined in the LTE specification.

The receiver 316 includes a low noise amplifier 320 (LNA), a transmitblocking filter 322, and an RF analog to digital converter ADC 324. Theinput of the LNA 320 is connected to the receive port of the duplexer314. The duplexer 314 typically provides high isolation between itstransmit port and its receive port. Nevertheless, the small component ofthe transmit signal that leaks through the duplexer 314 may becomparable to or larger than the received power at the input to the LNA320. To prevent the transmit signal from obscuring the received signalat the input to the RF ADC, the transmit blocking filter 322 is providedbetween the output of the LNA 320 and the input of the RF ADC 324. Thetransmit blocking filter 322, which may also be called an “ADC protectfilter,” is configured to pass the receive frequency range whilestopping, or substantially attenuating, the transmit frequency range.The digital output from the RF ADC 324 is provided to a processor (notshown) that demodulates and extracts data from the received signal.

FIG. 4 is a block diagram of an RF subsystem 400 for a communicationsdevice. The RF subsystem 400 includes a low bands radio 410 and amid/high bands radio 430. The low bands radio 410 may be configured forcommunicating in one or more LTE bands within a frequency range of about700 MHz to 1 GHz. The mid/high bands radio 430 may be configured forcommunicating in one or more LTE bands within a frequency range of about1.7 GHz to 2.7 GHz.

The low bands radio 410 includes a low bands antenna 412, a duplexerbank 414, a receiver 416, and a transmitter 418. The duplexer bank 414includes a plurality of duplexers for specific LTE bands. Each duplexerincludes a receive port for connection to the receiver 416, a transmitport for connection to the transmitter 418, and an antenna port forconnection to the antenna 412. Within each duplexer, a receive filter iscoupled between the receive port and the antenna port, and a transmitfilter is coupled between the antenna port and the transmit port. Eachreceive filter is configured to pass the receive frequency range of theassociated LTE band and each transmit filter is configured to pass thetransmit frequency range of the associated LTE band. The duplexer bandalso includes radio frequency (RF) switches to connect one or more ofthe duplexers to the antenna, receiver, and transmitter depending onwhat LTE band or bands are used for communications.

The receiver 416 includes one or more low noise amplifier 420 (LNA), amulti-band transmit blocking filter 422, and an RF analog to digitalconverter ADC 424. The input of the LNA 420 is connected to the receiveports of one or more duplexers in the duplexer bank 414. While a singleLNA 420 is shown, the receiver 416 may include a bank of LNAscorresponding to the bank of duplexers. In this case, the input of eachLNA may be connected to the receive port of the corresponding duplexer.The multi-band transmit blocking filter 422 is coupled between theoutput of the LNA 420 and the input the RF ADC 424. The digital outputfrom the RF ADC 424 is provided to a processor (not shown) thatdemodulates and extracts data from the received signal. The multi-bandtransmit blocking filter 422 is configured to pass the receivefrequencies of a group of two or more LTE bands, where a first receivefrequency range of a first band in the group and a second receivefrequency range of a second band in the group are disjoint(non-overlapping) and not subsets of a receive frequency range of athird band in the group. The multi-band transmit blocking filter 422 isalso configured to stop, or substantially attenuate, the transmitfrequencies of some or all of the bands in the group.

The mid/high bands radio 430 includes a mid/high bands antenna 432, aduplexer bank 434, a receiver 436, and a transmitter 438. The receiver436 includes one or more low noise amplifier 440 (LNA), a multi-bandtransmit blocking filter 442, and an RF analog to digital converter ADC444. Except for frequency range of operation, each of the elements ofthe mid/high bands receiver 430 functions analogously to thecorresponding elements of the low bands receiver 410.

FIG. 5 is a block diagram of another RF subsystem 500 for acommunications device. The RF subsystem 500 includes a low bands radio510 (which may be the same as the low bands radio 410 in the RFsubsystem 400), a mid bands radio 530, and a high bands radio 550. Thelow bands radio 510 may be configured for communicating in one or moreLTE bands within a frequency range of about 700 MHz to 1 GHz. The midbands radio 530 may be configured for communicating in one or more LTEbands within a frequency range of about 1.7 GHz to 2.2 GHz. The highbands radio 550 may be configured for communicating in one or more LTEbands within a frequency range of about 2.3 GHz to 2.7 GHz. The highbands radio 550 may also be configured to operate in the 2.4 GHzindustrial, scientific, and medical (ISM) band which may include Wi-Fi®and Bluetooth®.

Each of the low bands radio 510, the mid bands radio 530, and the highbands radio 550 includes a respective antenna 512/532/552, a duplexerbank 514/534/554, a receiver 516/536/556, and a transmitter 518/538/558.Each receiver includes one or more low noise amplifier 520/540/560), amulti-band transmit blocking filter 522/542/562, and an RF analog todigital converter 524/544/564. Except for frequency range of operation,each of these elements functions analogously to the correspondingelements of the low bands receiver 410 in the RF subsystem 400 of FIG.4.

FIG. 6 is block diagram of a low bands multi-band transmit blockingfilter suitable for use at 422 in the RF subsystem 400 or at 522 in theRF subsystem 500. It is not possible for a single filter to pass thereceive frequencies and stop the transmit frequencies of all lowfrequency LTE bands, simply because the transmit frequencies of somebands overlap the receive frequencies of other bands. Thus themulti-band transmit blocking filter 600 may include one or both of afirst dual-passband filter 610 and second dual-passband filter 620.

The first dual-passband filter 610 may pass receive frequencies and stoptransmit frequencies of LTE bands commonly used in North America andadjacent regions (NAR). For example, the first dual-passband filter 610may pass receive frequencies and stop transmit frequencies of some orall of LTE bands 5, 6, 12-14, 17-19, 26, and 67. This combination ofbands allows carrier aggregation using pairs of bands including, forexample, bands 5 and 12, bands 5 and 13, and bands 5 and 17. Example 1,to be discussed subsequently, is a dual-passband SAW filter suitable foruse at 610.

The second dual-passband filter 620 may pass receive frequencies andstop transmit frequencies of LTE bands commonly used in the rest of theworld (ROW) other than North America and adjacent regions. For example,the second dual-passband filter 620 may pass receive frequencies andstop transmit frequencies of some or all of LTE bands 8, 20, 28A, 28B,and 68. This combination of bands allows carrier aggregation using pairsof bands including, for example, bands 8 and 20, and bands 8 and 28.Example 2, to be discussed subsequently, is a dual-passband SAW filtersuitable for use at 620.

When both dual-passband filters 610, 620 are installed in the low bandsradio of a communications device, one of the dual-passband filters 610,620 may be selected for use (depending on the location of thecommunications device) by an RF switch 630. Alternatively, only one ofthe dual-passband filters 610, 620 may be installed in the low bandsradio. An inductor 640 may be used to match the output impedance of thedual-passband filters 610, 620 to the input impedance of the RF ADC suchas the RF ADC 424 or 524.

FIG. 7 is block diagram of a mid/high bands multi-band transmit blockingfilter 700 suitable for use at 442 in the RF subsystem 400. The mid/highbands multi-band transmit blocking filter 700 may include one or more ofa first mid-bands filter (MB1) 710, a second mid-bands filter (MB2) 720,and a high-bands filter 730. Without the high-bands filter 730, themulti-band transmit blocking filter 700 may be suitable for use at 542in the RF subsystem 500.

The first mid-bands filter 710 may be a band-pass filter configured topass receive frequencies and stop transmit frequencies of LTE bands 1,2, 4, 10, 26, and 66. This combination of bands allows carrieraggregation using pairs of bands including, for example, bands 2 and 4,and bands 2 and 66. Example 3, to be discussed subsequently, is a SAWband-pass filter suitable for use at 710.

The second mid-bands filter 720 may be a dual-passband filter configuredto pass receive frequencies and stop transmit frequencies of LTE bands1, 3, 4, 9, 10, 23, 65, and 66. This combination of bands allows carrieraggregation using pairs of bands including, for example, bands 1 and 3.Example 4, to be discussed subsequently, is a SAW dual-passband filtersuitable for use at 720.

The high-bands filter 730 may be a dual-passband filter configured topass receive frequencies and stop transmit frequencies of LTE bands 7and 30. This combination of bands allows carrier aggregation using bands7 and 30. The combination of the high-bands filter and one of themid-bands filters 710, 720 allows carrier aggregation using, forexample, bands 1 and 7; bands 1, 3, and 7; bands 2 and 7; bands 2 and30; bands 2, 4, and 7; bands 2, 4, and 30; and bands 2, 7, and 66.Example 5, to be discussed subsequently, is a SAW dual-passband filtersuitable for use at 730.

Selection of one or more of the filters 710, 720, 730 for use may beaccomplished using an RF switch at 740 or in some other manner aspreviously described.

FIG. 8 is a block diagram of a high-bands multi-band transmit blockingfilter 800 suitable for use at 522 in the RF subsystem 500. Themulti-band transmit blocking filter 800 may include one or both of afirst dual-passband filter 810 and second dual-passband filter 820.

The first dual-passband filter 810 may, for example, pass receivefrequencies and stop transmit frequencies of LTE band 7. The firstdual-passband filter 810 may also pass frequencies of LTE band 40 andthe 2.4-2.5 GHz ISM band. Both LTE band 40 and the ISM band use timedivision duplexing where the same frequencies are used for receptionsand transmission. The 2.4-2.5 GHz ISM band is used for variouscommunications protocols including Bluetooth and Wi-Fi in accordancewith IEEE 802.11(b), (g), and (n).

The second dual-passband filter 820 may, for example, pass receivefrequencies and stop transmit frequencies of LTE band 30. The seconddual-passband filter 820 may also pass frequencies of LTE band 38, LTEband 41, and the 2.4-2.5 GHz ISM band. These bands use time divisionduplexing where the same frequencies are used for receptions andtransmission.

Selection of one of the filters 810, 820 for use may be accomplishedusing an RF switch at 830. Alternatively, only one of the filters 810,820 may be installed in the communications device.

FIG. 9 is a block diagram of a dual-passband filter 900 suitable for useas a multi-band transmit blocking filter. The dual-passband filter 900includes a first band-pass filter 910 in parallel with a secondband-pass filter 920. Considered individually, the first band-passfilter 910 has low insertion loss for a first passband and higherinsertion loss for frequencies outside of the first passband, as shownin the graph 915 of S(1,2) (the input-output transfer function) of thefilter 910 as a function of frequency. Considered individually, thesecond band-pass filter 920 has low insertion loss for a secondpassband, higher in frequency than the first passband, and higherinsertion loss for frequencies outside of the second passband, as shownin the graph 925 of S(1,2) (the input-output transfer function) of thefilter 920 as a function of frequency.

The third chart 935 is a plot of S(1,2) for the dual-passband filter 900formed by the first and second band-pass filters 910, 920 connected inparallel. The dual-passband filter 900 provides a first passband, asecond passband higher in frequency than the first passband, a firststopband lower in frequency than the first passband, and a secondstopband between the first and second passbands. The insertion loss ofthe dual-passband filter 900 is low for both the first passband and thesecond passband as defined by the respective band-pass filter 910, 920.By controlling the phase of the transmission of the two band-passfilters 910, 920 for frequencies within the stopband, the insertion lossof the dual-passband filter 900 in at least one of the first and secondstopbands can be greater than the insertion loss of either constituentband-pass filter. Specifically, if the transmission through the twoband-pass filters 910, 920 at a particular frequency has similaramplitude and a phase difference of about 180 degrees, the transmissionsthrough the two filters will cancel to some extent, such that insertionloss of the two filters in parallel is greater than the insertion lossof either filter in isolation.

Example 1

FIG. 10 is a schematic diagram of a dual-passband SAW filter 1000suitable for use as the first low band filter 610. The dual-passbandfilter 1000 includes a first band pass filter 1010 and a secondband-pass filter 1020 in parallel. The first band-pass filter 1010 isformed by series SAW resonators R1 and R3, shunt SAW resonators R2 andR4, and inductor L2. The second band-pass filter 1020 is formed byseries SAW resonators R5 and R7, shunt SAW resonators R6 and R8, andinductor L3. Inductors L1 may be present to adjust the input and outputimpedance of the dual-passband filter. Values of these components areprovided in the table within FIG. 10.

FIG. 11 is a graph of the input-output transfer function S(1,2) versusfrequency for the dual-passband filter 1000 of FIG. 10. Thedual-passband filter 1000 provides a first passband, a second passbandhigher in frequency than the first passband, a first stopband lower infrequency than the first passband, and a second stopband between thefirst and second passbands. The receive frequencies (white bars) andtransmit frequencies (shaded bars) of various LTE bands are shown abovethe graph on the same frequency axis. The first pass band includes thereceive frequencies of LTE bands 12-14, 17, and 67. The second pass bandincludes the receive frequencies of LTE bands 5, 6, 18, 19, and 26. Thedual-passband filter 100 stops (i.e. provides at least 30 dBattenuation) the transmit frequencies of the same bands (with theexception of band 67, is which is a receive-only band).

Note the first band-pass filter 1010 could be considered a multi-bandfilter in its own right since it passes the receive frequencies of agroup of LTE bands (i.e. LTE band 12, 13, 14, 17, and 67 where thereceive frequency ranges of LTE bands 12 and 14 are disjoint and not asubset of the receive frequency range of any other band in the group.The second band-pass filter 1020 is not a multi-band filter aspreviously defined since the receive frequencies of LTE bands 5, 6, 18,and 19 are all subsets of the receive frequency range of LTE band 26.

Example 2

FIG. 12 is a schematic diagram of a dual-passband SAW filter 1200suitable for use as the second low band filter 620. The dual-passbandfilter 1200 includes a first band-pass filter 1210 and a secondband-pass filter 1220 in parallel. The first band-pass filter 1210 isformed by series SAW resonators R3 and R5, shunt SAW resonators R1, R2,R4, and R6, and inductor L2. The second band-pass filter 1220 is formedby series SAW resonators R7 and R9, shunt SAW resonators R8 and R10, andinductor L3. Inductors L1 may be present to adjust the input and outputimpedance of the dual-passband filter. Values of these components areprovided in the table within FIG. 12.

FIG. 13 is a graph of the input-output transfer function S(1,2) versusfrequency for the dual-passband filter 1200 of FIG. 12. Thedual-passband filter 1200 provides a first passband, a second passbandhigher in frequency than the first passband, a first stopband lower infrequency than the first passband, and a second stopband between thefirst and second passbands. The receive frequencies (white bars) andtransmit frequencies (shaded bars) of various LTE bands are shown abovethe graph on the same frequency axis. The dual-passband filter 1200passes the receive frequencies of LTE bands 8, 20, 28A, 28B, and 68 withno more than a few dB loss, while stopping (providing at least 30 dBattenuation) the transmit frequencies of the same bands.

Example 3

FIG. 14 is a schematic diagram of a SAW filter 1400 suitable for use asthe first mid band filter 710. The SAW filter 1400 is wide band-passfilter rather than a dual-passband filter. The filter 1400 is formed byseries SAW resonators R3, R5, R7, and R9, shunt SAW resonators R1, R2,R4, R6, R8, R10, and R11, and inductor L3. Inductors L1 and L2 may bepresent to adjust the input and output impedance of the filter. Valuesof these components are provided in the table within FIG. 14.

FIG. 15 is a graph of the input-output transfer function S(1,2) versusfrequency for the filter 1400 of FIG. 14. The receive frequencies (whitebars) and transmit frequencies (shaded bars) of various LTE bands areshown above the graph on the same frequency axis. The filter 1400 passesthe receive frequencies of LTE bands 1, 2, 4, 10, 25, and 66 with nomore than a few dB loss, while stopping (providing at least 30 dBattenuation) the transmit frequencies LTE bands 2, 4, 10, 25, and 66.Note that the transmit frequencies of LTE band 1 are not stopped by thefilter 1400, such that band 1 can be used for receive only.

Example 4

FIG. 16 is a schematic diagram of a dual-passband SAW filter 1600suitable for use as the second mid band filter 720. The dual-passbandfilter 1600 includes a first band pass filter 1610 and a secondband-pass filter 1620 in parallel. The first band-pass filter 1610 isformed by series SAW resonators R1 and R3, shunt SAW resonators R2 andR4, and inductor L2. The second band-pass filter 1620 is formed byseries SAW resonators R5 and R7, shunt SAW resonators R6 and R8, andinductor L3. Inductors L1 may be present to adjust the input and outputimpedance of the dual-passband filter. Values of these components areprovided in the table within FIG. 16.

FIG. 17 is a graph of the input-output transfer function S(1,2) versusfrequency for the dual-passband filter 1600 of FIG. 16. Thedual-passband filter 1600 provides a first passband, a second passbandhigher in frequency than the first passband, a first stopband lower infrequency than the first passband, and a second stopband between thefirst and second passbands. The receive frequencies (white bars) andtransmit frequencies (shaded bars) of various LTE bands are shown abovethe graph on the same frequency axis. The dual-passband filter 1600passes the receive frequencies of LTE bands 1, 3, 4, 9, 10, 23, 65, and66 with no more than a few dB loss, while stopping (providing at least30 dB attenuation) the transmit frequencies of the same bands.

Example 5

FIG. 18 is a schematic diagram of a dual-passband SAW filter 1800suitable for use as the high band filter 730. The dual-passband filter1800 includes a first band pass filter 1810 and a second band-passfilter 1820 in parallel. The first band-pass filter 1810 is formed byseries SAW resonators R1 and R3, shunt SAW resonators R2, and inductorL2. The second band-pass filter 1820 is formed by series SAW resonatorsR4 and R6, shunt SAW resonators R5 and R7, and inductor L3. Inductors L1may be present to adjust the input and output impedance of thedual-passband filter. Values of these components are provided in thetable within FIG. 18.

FIG. 19 is a graph of the input-output transfer function S(1,2) versusfrequency for the dual-passband filter 1800 of FIG. 18. Thedual-passband filter 1800 provides a first passband, a second passbandhigher in frequency than the first passband, a first stopband lower infrequency than the first passband, and a second stopband between thefirst and second passbands. The receive frequencies (white bars) andtransmit frequencies (shaded bars) of various LTE bands are shown abovethe graph on the same frequency axis. The dual-passband filter 1800passes the receive frequencies of LTE bands 7 and 30 with no more than afew dB loss, while stopping (providing at least 30 dB attenuation) thetransmit frequencies of the same bands.

Closing Comments

Throughout this description, the embodiments and examples shown shouldbe considered as exemplars, rather than limitations on the apparatus andprocedures disclosed or claimed. Although many of the examples presentedherein involve specific combinations of method acts or system elements,it should be understood that those acts and those elements may becombined in other ways to accomplish the same objectives. With regard toflowcharts, additional and fewer steps may be taken, and the steps asshown may be combined or further refined to achieve the methodsdescribed herein. Acts, elements and features discussed only inconnection with one embodiment are not intended to be excluded from asimilar role in other embodiments.

As used herein, “plurality” means two or more. As used herein, a “set”of items may include one or more of such items. As used herein, whetherin the written description or the claims, the terms “comprising”,“including”, “carrying”, “having”, “containing”, “involving”, and thelike are to be understood to be open-ended, i.e., to mean including butnot limited to. Only the transitional phrases “consisting of” and“consisting essentially of”, respectively, are closed or semi-closedtransitional phrases with respect to claims. Use of ordinal terms suchas “first”, “second”, “third”, etc., in the claims to modify a claimelement does not by itself connote any priority, precedence, or order ofone claim element over another or the temporal order in which acts of amethod are performed, but are used merely as labels to distinguish oneclaim element having a certain name from another element having a samename (but for use of the ordinal term) to distinguish the claimelements. As used herein, “and/or” means that the listed items arealternatives, but the alternatives also include any combination of thelisted items.

It is claimed:
 1. A communications receiver comprising: a low noiseamplifier; a multi-band transmit blocking filter having a first portconnected to an output of the low noise amplifier; and an RFanalog-to-digital converter having an input connected to a second portof the multi-band transmit blocking filter, wherein the multi-bandtransmit filter is configured to pass the receive frequencies of a groupof two or more LTE (long term evolution) bands, where a first receivefrequency range of a first band in the group and a second receivefrequency range of a second band in the group are disjoint and notsubsets of a receive frequency range of a third band in the group, andstop the transmit frequencies of at least some bands in the group. 2.The communications receiver of claim 1, wherein the multi-band transmitblocking filter comprises: a first dual-passband filter having a firstpassband, a second passband higher in frequency than the first passband,a first stopband lower in frequency than the first passband, and asecond stopband between the first and second passbands.
 3. Thecommunications receiver of claim 2, wherein the first dual-passbandfilter is configured to pass receive frequencies and stop transmitfrequencies of LTE bands 5, 6, 12, 13, 14, 17, 18, 19, 26, and
 67. 4.The communications receiver of claim 2, wherein the first dual-passbandfilter is configured to pass the receive frequencies and stop thetransmit frequencies of LTE bands 8, 20, 28A, 28B, and
 68. 5. Thecommunications receiver of claim 4, wherein the multi-band transmitblocking filter further comprises: a second dual-passband filterconfigured to pass the receive frequencies and stop the transmitfrequencies of LTE bands 5, 6, 12, 13, 14, 17, 18, 19, 26, and 67; and aswitch to select one of the first dual-passband filter and the seconddual-passband filter.
 6. The communications receiver of claim 2, whereinthe first dual-passband filter is configured to pass the receivefrequencies and stop the transmit frequencies of LTE bands 1, 3, 4, 9,10, 23, 65, and
 66. 7. The communications receiver of claim 6, whereinthe multi-band transmit blocking filter further comprises: asingle-passband filter configured to pass the receive frequencies andstop the transmit frequencies of LTE bands 2, 4, 10, 25, and 66; and aswitch to select one of the first dual-passband filter and thesingle-passband filter.
 8. The communications receiver of claim 7,wherein the multi-band transmit blocking filter further comprises: asecond dual-passband filter configured to pass the receive frequenciesand stop the transmit frequencies of LTE bands 7 and
 30. 9. Thecommunications receiver of claim 2, wherein the first dual-passbandfilter is configured to pass the receive frequencies and stop thetransmit frequencies of LTE band 7 and to pass the frequencies of LTEband 40 and the 2.4 GHz ISM (Industrial, Scientific, Medical) band. 10.The communications receiver of claim 9, wherein the multi-band transmitblocking filter further comprises: a single-passband filter configuredto pass the receive frequencies and stop the transmit frequencies of LTEband 30, to pass the frequencies of the 2.4 GHz ISM (Industrial,Scientific, Medical) band and LTE bands 38 and 41; and a switch toselect one of the first dual-passband filter and the single-passbandfilter.
 11. The communications receiver of claim 2, wherein the firstdual passband filter comprises: a first surface acoustic wave (SAW)band-pass filter in parallel with a second SAW band-pass filter,wherein: the first SAW band-pass filter defines the first passband, andthe second SAW band-pass filter defines the second passband.
 12. Thecommunications receiver of claim 11, wherein relative phases transferfunctions of the first and second SAW band-pass filters in at least oneof the first and second stop bands are controlled such that an insertionloss of the first dual passband filter is greater than insertion lossesof both the first and second SAW band-pass filters in isolation for atleast one frequency in the at least one of the first and second stopbands.
 13. A communications device, comprising: a low bands receiverconfigured to receive one or more LTE (long term evolution) bandsbetween 700 MHz and 1 GHz, the low bands receiver comprising: a lowbands low noise amplifier, a low bands transmit blocking filter having afirst port connected to an output of the low bands low noise amplifier,and a low bands RF analog-to-digital converter having an input connectedto a second port of the low bands transmit blocking filter; and a midbands receiver configured to receive one or more LTE (long termevolution) bands between 1.7 GHz and 2.2 GHz, the mid bands receivercomprising: a mid bands low noise amplifier, a mid bands transmitblocking filter having a first port connected to an output of the midbands low noise amplifier, and a mid bands RF analog-to-digitalconverter having an input connected to a second port of the mid bandstransmit blocking filter.
 14. The communications device of claim 13,wherein the low bands transmit blocking filter is configured to: passthe receive frequencies of a first group of two or more LTE bands, wherea first receive frequency range of a first band in the first group and asecond receive frequency range of a second band in the first group aredisjoint and not subsets of a receive frequency range of a third band inthe first group, and stop the transmit frequencies of at least somebands in the first group.
 15. The communications device of claim 14,wherein the low bands transmit blocking filter comprises: a firstdual-passband filter configured to pass receive frequencies and stoptransmit frequencies of LTE bands 5, 6, 12, 13, 14, 17, 18, 19, 26, and67.
 16. The communications device of claim 14, wherein the low bandstransmit blocking filter comprises: a first dual-passband filterconfigured to pass the receive frequencies and stop the transmitfrequencies of LTE bands 8, 20, 28A, 28B, and
 68. 17. The communicationsdevice of claim 16, wherein the low bands transmit blocking filterfurther comprises: a second dual-passband filter configured to pass thereceive frequencies and stop the transmit frequencies of LTE bands 5, 6,12, 13, 14, 17, 18, 19, 26, and 67; and a switch to select one of thefirst dual-passband filter and the second dual-passband filter.
 18. Thecommunications device of claim 13, wherein the mid bands transmitblocking filter is configured to: pass the receive frequencies of asecond group of two or more LTE bands, where a first receive frequencyrange of a first band in the second group and a second receive frequencyrange of a second band in the second group are disjoint and not subsetsof a receive frequency range of a third band in the second group, andstop the transmit frequencies of at least some bands in the secondgroup.
 19. The communications device of claim 18, wherein the mid bandstransmit blocking filter comprises: a third dual-passband filterconfigured to pass the receive frequencies and stop the transmitfrequencies of LTE bands 1, 3, 4, 9, 10, 23, 65, and
 66. 20. Thecommunications device of claim 19, wherein the mid bands transmitblocking filter further comprises: a first single-passband filterconfigured to pass the receive frequencies and stop the transmitfrequencies of LTE bands 2, 4, 10, 25, and 66; and a switch to selectone of the third dual-passband filter and the first single-passbandfilter.
 21. The communications device of claim 20, wherein the mid bandstransmit blocking filter further comprises: a fourth dual-passbandfilter configured to pass the receive frequencies and stop the transmitfrequencies of LTE bands 7 and
 30. 22. The communications device ofclaim 13, further comprising: a high bands receiver configured toreceive one or more bands between 2.3 GHz and 2.7 GHz, the high bandsreceiver comprising: a high bands low noise amplifier, a high bandstransmit blocking filter having a first port connected to an output ofthe high bands low noise amplifier, and a high bands RFanalog-to-digital converter having an input connected to a second portof the high bands transmit blocking filter.
 23. The communicationsdevice of claim 22, wherein the high bands transmit blocking filtercomprises: a fifth dual-passband filter configured to pass the receivefrequencies and stop the transmit frequencies of LTE band 7 and to passthe frequencies of LTE band 40 and the 2.4 GHz ISM (Industrial,Scientific, Medical) band.
 24. The communications device of claim 23,wherein the high bands transmit blocking filter further comprises: asecond single-passband filter configured to pass the receive frequenciesand stop the transmit frequencies of LTE band 30, to pass thefrequencies of the 2.4 GHz ISM band and LTE bands 38 and 41; and aswitch to select one of the fifth dual-passband filter and the secondsingle-passband filter.